Numerical simulations of baroclinic driven flows in a thermally driven rotating annulus using the immersed boundary method

von Larcher, Thomas; Dörnbrack, Andreas

Meteorologische Zeitschrift Vol. 23 No. 6 (2015), p. 599 - 610

48 références bibliographiques

publié: Jan 13, 2015
publication en ligne: Nov 14, 2014
manuscrit accepté: Aug 11, 2014
revision du manuscrit reçu: Jul 17, 2014
révision du manuscrit demandée: Jun 23, 2014
manuscrit reçu: Apr 16, 2014

DOI: 10.1127/metz/2014/0609

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We present results of numerical simulations of baroclinic driven flows in the thermally driven rotating annulus using the immersed boundary method for modeling of the boundary conditions. The Navier-Stokes equations in the Boussinesq approximation are solved in the Eulerian flux-form advection scheme with the geophysical flow solver EULAG as numerical framework. We test our approach against results of an appropriate laboratory experiment with water as working fluid and directly aim at the wavy flow regime where complex flows and regular wave patterns are generally observed but where centrifugal effects and turbulence is of minor importance. Multivariate statistical methods are used for analyzing time series of computed temperature data. We, here, present the outcome of the time series data analysis at particular parameter points, and specifically analyze a complex wave-wave interaction, and, secondly, a wave mode switch where the azimuthal wave number changes to the next higher one. The numerical results are highly consistent with the experimental observations. That encourage us to focus on our actual goal as the next step, that is the irregular flow regime found at large rotation rates where the centrifugal force has an increasing effect on flow states and where multiple scale flows are generally observed.


baroclinic driven flowsthermally driven rotating annulusnumerical experimentsimmersed boundary methodcomplex flow regimesmultivariate time series analysis